KR20200031877A - Cassette type injection molding apparatus for manufacturing of silicone products - Google Patents

Abstract

The present invention relates to an injection molding apparatus. More specifically, the present invention provides a cassette-type injection molding apparatus for producing silicone molded products, which is provided with a plurality of cassette assemblies, each having a cavity, to produce various kinds or a large quantity of silicone molded products. The cassette-type injection molding apparatus may comprise: an upper plate and a lower plate, installed to vertically open and close between an upper fixing plate and a lower fixing plate; a main mold part including an upper frame installed below the upper plate and a lower frame installed above the lower plate, the upper frame including an upper receiving groove on a parting surface thereof, and the lower frame including a lower receiving groove on a parting surface thereof; insert mold parts installed releasably in the receiving grooves of the main mold part and including, on parting surfaces thereof, an insert upper core and an insert lower core that together form a cavity of a molded product; a cold runner part installed in the main mold part so as to connect to the insert mold parts, to inject a silicone liquid resin into the cavity; and a heating unit including a first heating pipe and a second heating pipe that are inserted through the upper plate and the lower plate of the main mold part, respectively, to generate heat and cure the silicone liquid resin.

Description

Cassette type injection mold device for manufacturing silicone molded products {CASSETTE TYPE INJECTION MOLDING APPARATUS FOR MANUFACTURING OF SILICONE PRODUCTS}

The present invention relates to an injection mold apparatus, and a cassette type injection mold apparatus for manufacturing a silicone molded product, which is provided with a plurality of cassette assemblies having respective cavities to manufacture multiple or large quantities of silicone molded products. .

In general, the lens for automobile headlamps uses a glass lens, but due to the thickness or weight of the glass lens, a lens made of plastic, which is an aspherical lens, was used in accordance with the trend of weight reduction.

Moreover, recently, a technology of applying a lens made of silicon as a lens for an automobile headlamp instead of a lens made of plastic has been disclosed. These silicone lenses are lightweight and have high elasticity, which minimizes the possibility of lens detachment even when an impact occurs.

However, although such a lens for automobile headlamps made of silicon is manufactured through transfer molding equipment, in the case of conventional transfer molding equipment, the molding resin is pressurized by the working pressure of the plunger, depending on the movement speed of the plunger. Not only does it take a long time to form, there is a problem that speed control is difficult.

In addition, the transfer molding equipment has a problem that there is a large amount of resin wasted due to the structural aspect, there is a difficulty in controlling the curing rate.

In addition, a lens made of silicon was also manufactured using an injection molding mold. The injection molding mold of a typical plastic product is injected and filled with a resin melted at an appropriate temperature in a cavity of a mold having a product shape at an appropriate pressure and speed, and then, after a certain period of time, the filled resin is cooled and solidified. While molded products are manufactured by opening the molded product by opening the mold, silicone resin is used to mold the lens made of silicone, which is injected with liquid silicone resin at room temperature into the cavity and heated to insert the lens. You will use the production method.

That is, if an injection molding mold using a normal thermoplastic resin is a method of manufacturing a product by cooling a heated resin, a silicone molding mold is a method of manufacturing a product by heating a resin that is not heated, and injecting a lens of silicone material. In the case of molding into a mold, the temperature control must be intensive because it is very sensitive to deformation due to shrinkage due to the properties of the thermosetting silicone resin, but it is difficult to control the temperature with a conventional injection molding mold, especially with a small size of the lens. Therefore, there is a problem in that it is more difficult to control this temperature due to the condition that a plurality of cavities are formed in one mold to simultaneously manufacture a large amount of lenses.

For this reason, conventional transfer molding equipment and injection molding molds are difficult to mass-produce, and it is difficult to simultaneously manufacture products of various shapes.

Korean Patent Publication No. 10-2017-0090614

The present invention has been devised to solve the above problems, and the cassette type injection mold apparatus for manufacturing the silicone molded product of the present invention is capable of producing multiple or large quantities of lenses, and enables individual temperature management of molded products. It is an object to provide a mold.

Particularly, the present invention has another object to provide a mold that is easy to replace the core according to a shape or a dimension change of a molded product, and is configured to use a conventional mold machine.

In order to solve the above problems, the cassette-type injection mold apparatus for manufacturing the silicone molded product of the present invention is a cassette-type mold apparatus in which an insert mold portion is installed and opened and operated inside the main mold portion, and upper and lower fixing plates are operated. An upper frame and a lower plate which are installed to open and close between the upper and lower plates, and an upper frame that is installed on the lower side of the upper plate to form an upper receiving groove on the molded surface, and a lower receiving groove on the molded surface that is installed on the upper of the lower mold The main mold part including the formed lower frame and the main mold part are respectively detachably installed in the receiving grooves, and the insert mold part and the insert mold part including the insert upper core and the insert lower core to form a cavity of the molded product on the molded surface Cold runner part installed in the main mold part to be connected to the mold part to inject silicone liquid resin into the cavity, and By respectively inserted in the mold of the upper molds and the lower molds to generate heat can include a heating portion provided with a first heating piping and the second heating pipe to cure the silicone resin solution.

On the other hand, a plurality of insert mold parts are provided, and each insert mold part is formed with a cavity having at least one shape as a cassette assembly, and the insert mold part is characterized in that an auxiliary heating means is buried.

Here, the auxiliary heating means includes a first auxiliary heating line located on the upper surface of the insert upper core and a second auxiliary heating line located on the lower surface of the insert lower core, and the heating lines are bent in a curved shape along a horizontal surface. It is formed as a path, and is characterized by being formed in a different shape according to the shape of the product.

At this time, the insert mold portion includes an insert upper fixing plate for fixing the insert upper core to the upper mold plate, and an insert fixing plate for fixing the insert lower core to the lower mold plate, and the insert mold portion is installed at the lower side of the fixing plate to form a molded product. It may be further provided with an insert taking-out means operating for taking out, each of the insert mold portion is characterized in that the insert taking-out means for taking out the product is provided separately.

The apparatus of the present invention can shorten the molding time compared to the conventional transfer molding method using a plunger as the lens is manufactured by the injection molding method. Particularly, the present invention has an effect that the insert mold part provided with a plurality of cassette assemblies is mounted on the main mold part, and this is a structure capable of injection molding at a time, and the production amount can be increased more than twice as compared with the conventional injection molding method. . That is, even in the case of a conventional injection molding machine, multiple cavities can be formed in one core, but it is appropriate considering the moving distance of the resin injected through the runner, the size or shape of the product, and the size of the core itself. Since the number of cavities is designed by number, the injection mold apparatus according to the present invention can have multiple such cores by mounting a plurality of insert mold parts, and thus has a production amount more than twice as many as the number of mounted cores.

In addition, the injection mold apparatus according to the present invention is made of a detachable structure of the insert mold part as a fastening member to the main mold part, so it is easy to replace, so it is very easy to replace the core according to the shape or dimension change of the molded product. There is an effect.

Moreover, since the injection mold apparatus according to the present invention can use the existing mold machine as it is, it has the advantage that it can significantly reduce the cost required for the production of a separate mold.

In particular, by installing a cold runner instead of a hot runner to mold a molded product made of silicone material, the silicone resin can be injected into the cavity while maintaining a low temperature to prevent solidification of the resin, and the cold of one block body Since the runner part is provided with a structure that can connect the runner to a plurality of insert mold parts, it has an advantage that resin can be injected into each cavity at the same time.

In addition to this, the injection mold apparatus according to the present invention is equipped with an additional insert mold part having a cavity of a different shape, so that one or more products, that is, a plurality of molded products can be manufactured by one injection molding. It has the effect that it is possible to produce multiple varieties with a mold device. In other words, it is possible to form multiple products or to injection mold multiple (multiple) products at once, thereby increasing productivity.

On the other hand, each insert mold part is provided with an auxiliary heating means designed to have a proper interval and temperature in response to a cavity, that is, a shape or thickness of a product to be molded, so that the heating part of the entire mold is redesigned according to core replacement, In addition to not having to reset the temperature of the heating unit, it is not necessary to perform temperature management for each core, so it has an effect of easy production management.

That is, when injection molding is performed by mounting additional insert mold parts having different cavities, it is difficult to manage heat for each core due to different shapes or sizes. In the injection mold apparatus according to the present invention, a heating part installed in the main mold part Separately from each insert mold part, since an auxiliary heating means is provided, it has the advantage of easy individual management. In other words, when a lens made of silicon is manufactured by an existing injection molding mold, the thickness or shape of the lens On the other hand, it was difficult to manage heat / temperature such as heat shrinkage, etc., whereas the injection mold apparatus according to the present invention has an advantage of easy heat / temperature management since auxiliary heating means are provided according to the shape of each cavity.

1 is a perspective view of an injection mold apparatus according to the present invention.
2 is a cross-sectional view taken along line A-A 'of the injection mold apparatus according to the present invention.
3 is a cross-sectional perspective view of the B-B 'line of the injection mold apparatus according to the present invention.
Figure 4 is an exploded perspective view showing an insert mold portion of the injection mold apparatus according to the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms.

This embodiment in the present specification is to provide a complete disclosure of the present invention, and to fully inform the scope of the invention to those skilled in the art to which the present invention pertains. And the present invention is only defined by the scope of the claims. Thus, in some embodiments, well-known components, well-known operations, and well-known techniques are not specifically described in order to avoid obscuring the present invention.

The same reference numerals refer to the same components throughout the specification. In addition, the terms (referred to) used in this specification are for describing the embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless otherwise specified in the phrase. Also, components and actions recited as “includes (or is provided with)” do not exclude the presence or addition of one or more other components and actions.

Unless otherwise defined, all terms (including technical and scientific terms) used in the present specification may be used as meanings commonly understood by those skilled in the art to which the present invention pertains. In addition, terms that are defined in a commonly used dictionary are not ideally or excessively interpreted unless defined.

Hereinafter, the technical features of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to an injection mold, which uses a cassette type injection mold, but relates to a mold capable of manufacturing a silicone molded product by injecting silicone resin.

The molded product handled in the present invention is a lens for a headlamp used in a vehicle, and is formed of a lens made of silicone, unlike a lens made of plastic, and silicone for injecting and molding silicone liquid resin to manufacture it An injection mold device for a molded product is provided.

That is, the present invention, unlike the conventional injection molding method of injecting molten plastic resin into a cavity in a mold and taking out a hard plastic injection material in a mold, inject silicone heat in a liquid form into a cavity at room temperature and heat It relates to a silicone product injection mold of a method of curing the silicone product to obtain an injection product.

At this time, the liquid silicone resin (LSR: Liquid Slicone Rubber) used is a thermosetting material, which is hardened by heating in a liquid form to have a shape.

1 to 4 show an injection mold apparatus 10 according to the invention. As shown in the figure, the injection mold apparatus 10 according to the present invention includes an main mold part 100 that is opened and closed vertically, and is mounted in the main mold part 100 to insert a mold to form a cavity of a product It comprises a part 200, a cold runner part 300 for injecting resin into the cavity, and a heating part 400 for heating to an appropriate temperature for product molding.

Here, the injection mold apparatus 10 according to the present invention is a structure in which the insert mold part 200 is mounted in a cassette structure in the main mold part 100 as one assembly, and a plurality of assemblies as shown in the drawing It is made with.

That is, the present invention operates as a cassette-shaped mold by mounting the insert mold portion 200 to an existing injection mold, and has a large amount and multiple cavities as it has a plurality of insert mold portions 200. .

First, the main mold part 100 is formed in the same way as a normal injection mold structure, and may be divided into an upper mold 101 and a lower mold 102 that open and close and operate. The upper part of the upper mold is provided with a connecting tube (100a) for mounting the sprue so that the resin can be introduced.

On the upper mold 101, the upper fixing plate 110 is positioned on the upper side, and the upper molding plate 120 is installed below the upper fixing plate 110. The upper frame 130 is fixedly installed on the lower surface of the upper mold plate 120, and the upper frame 130 is provided with an upper receiving groove 131 for accommodating the upper part of the insert mold part 200.

The lower mold plate 102 has a lower fixing plate 160 positioned on the lower side, and an upper mold plate 150 is installed above the lower fixing plate 160. The lower frame 140 is fixedly installed on the upper surface of the lower mold plate 150, and the lower frame 140 is provided with a lower receiving groove 141 for accommodating the lower part of the insert mold part 200.

That is, the upper accommodating groove 131 and the lower accommodating groove 141 form an integral accommodating portion on the molded surface, and an insert mold part 200 is installed in the accommodating portion.

Here, the receiving portion of the main mold part 100 may be formed in the form of a mounting groove on the upper frame 130 and the lower frame 140, but as shown in the drawing, the insert mold part 200 is completely inserted and mounted It is preferably formed to be through, so that the upper and lower parts of the insert mold part 200 are disposed to contact the upper mold plate 120 and the lower mold plate 150, respectively.

The main mold part 100 is provided with driving devices such that the upper mold 101 and the lower mold 102 are opened and closed, and the lower mold can be provided with upper and lower plates to drive separate ejector pins. However, since its configuration and operation method are similar to those of the conventional one, detailed description will be omitted.

Here, a cold runner part 300 for injecting resin may be provided in the upper mold of the main mold part 100.

The cold runner part 300 is provided in place of the hot runner part of an existing injection mold machine, and a cold runner block provided with a low temperature holding part maintaining a relatively low temperature compared to a mold cavity so that the silicone liquid material is not cured by heat. A sieve may be used, and is provided by being stacked under the upper fixing plate 110.

The cold runner part 300 fills the silicone liquid resin through the connecting pipe 100a of the main mold part 100, and the runner nozzle 310 is formed toward the lower side.

In this case, a communication hole 101a may be formed in the upper mold 101 of the main mold part 100 so as to communicate with the runner nozzle 310 of the cold runner part 300, and the cold runner part 300 may have a runner nozzle. 310 is connected to the communication hole (101a).

Here, the cold runner part 300, as the mold of the present invention is provided in a cassette-type structure, is distributed to a plurality of runners and injected into each runner inlet to inject resin into the insert mold part 200 provided in plural. It is formed to be positioned correspondingly.

On the other hand, in the main mold part 100, a cavity, that is, a heating part 400 is installed to preheat the insert mold part 200, the heating part 400 may be provided in the form of a heating plate, but the practice of the present invention The example shows that it is provided in the form of a cartridge rod heater that is inserted through the upper mold and the lower mold.

That is, the heating unit 400 includes a first heating pipe 410 inserted through the upper mold plate 120 and a second heating pipe 420 inserted through the lower mold plate 150, the upper mold and the lower mold. As the mold is preheated, heat is applied to the insert mold part 200.

On the other hand, the insert mold portion 200 is inserted into the receiving portion of the main mold portion 100 in a cassette structure, the insert mold portion 200 is inserted into the upper receiving groove 131 of the upper frame 130 It includes a core 220 and an insert lower core 230 installed in the lower receiving groove 141 of the lower frame 140.

Here, the insert upper core 220 and the insert lower core 230 are molded to each other, and the cavity C of the molded product is dividedly formed on the mating surface.

The insert upper core 220 and the insert lower core 230 are inserted and installed in the respective receiving grooves of the main mold part 100, because they are fastened by a fastening member (not shown) to be detachable from the main mold part 100. Is fixed accordingly.

At this time, the insert upper core 220 is fixed by being fastened to the insert upper plate 210, and is fixedly installed in the upper mold 101 as the insert upper plate 210 is bolted to the upper mold plate 120 with a fastening bolt 203. Being, the insert lower core 230 is fastened to the insert lower plate 240, and is fixedly installed in the lower mold 102 as the insert lower plate 240 is bolted to the lower mold plate 150.

The insert lower plate 240 is stacked on the insert fixing plate 250, and the insert fixing plate 250 is provided with an insert taking-out means for taking out the product. The insert taking-out means is provided to be interlocked with the upper and lower plates of the main mold part 100 so as to take out molded products.

As such, the insert upper core 220 is substantially coupled to the upper plate 120, and the insert lower core 230 is provided in a form that is coupled to the lower plate 150.

As such, the insert upper core 220 and the insert lower core 230 are detachably installed in the receiving grooves of each frame of the main mold part 100. That is, when forming a molded product of different shape or different size, a replacement operation is required. As the insert mold portion 200 according to the present invention is detachably coupled to the main mold portion 100 by a fastening member, this replacement operation is performed. This can be easily performed.

At this time, the insert upper core 220 is provided with an insert runner ball 201 formed to communicate with the communication hole 101a, and as the cavity formed inside the core and the cold runner part 300 are connected, they are brought into the cavity. The silicone liquid resin can be injected.

In the present invention, the cavity C of the insert mold part 200 is formed to have a lens shape. In the drawing, although one cavity C is formed for each insert mold part 200, multiple lenses are molded. It is preferably formed of a plurality of cavities (C) arranged in the horizontal direction, these cavities are connected to the insert runner ball 201 by the runner (R) and the gate (G). That is, the runners G are distributed from the insert runner groove 201a of the insert lower core 230 and are connected to the cavity C through the gate G.

An auxiliary heating means 450 may be provided in the insert mold part 200.

The auxiliary heating means 450 is for transferring heat to the cavity of the insert mold part 200 together with the heating part 400 provided in the main mold part 100, and by setting a direct temperature for the cavity, the molded product It is induced to cure at an appropriate temperature.

The auxiliary heating means 450 may be buried in the insert mold part 200, and the first auxiliary heating line 451 and the second inserted into the insert upper core 220 and the insert lower core 230, respectively. It includes an auxiliary heating line (452).

At this time, the insert mold portion 200 may be provided with line grooves 450a and 450b for accommodating auxiliary heating lines of the auxiliary heating means 450, the upper surface of the insert upper core 220 and the lower insert core 230 ) May be formed in a groove shape, respectively, but preferably, the lower surface of the insert upper plate 210 and the lower surface of the insert lower plate 240 stacked on the upper and lower sides of the insert upper core 220 and the insert lower core 230. It is preferable that each of the line grooves 450a and 450b is formed on the upper surface to be inserted into and fixed in the groove.

Here, the auxiliary heating means 450 is preferably provided to have a predetermined temperature or shape corresponding to the shape or size of the cavity formed in the insert mold part 200, that is, depending on the thickness of the lens, which is a molded product to be actually manufactured. It may be provided in consideration of thermal deformation after the injection operation, and the shape may be formed to have a curved path of a curved shape along a horizontal plane.

Since the auxiliary heating means 450 is located close to the cavity C, it is faster and easier to transfer heat than the heating part 400, and is provided only individually with the heating part 400 by being individually provided in response to a cavity having a different shape. Compared to temperature control, it is possible to control different temperatures for each cavity, thereby making it possible to produce multiple types of lenses.

At this time, in the injection mold apparatus according to the present invention, as the insert mold part 200 is provided in plural, the quantity of the assembly can be configured differently according to the overall size of the mold.

As an example, the insert mold part 200 according to the present invention may be provided as a six-cassette assembly and installed as shown in the drawings, and each insert mold part may manufacture an A-type lens and a B-type lens. It is provided with two types of assemblies so that three are mounted on the main mold part 100, and it is preferable that auxiliary heating means 450 are provided for each type of lens.

As a result, two types of lenses can be simultaneously produced in one injection molding operation, and instead of having a plurality of cavities of different shapes in one core, a plurality of cores can be mounted, and each core is different. By providing a cavity having a shape, it is possible to manufacture multiple types of lenses in one mold.

The injection mold apparatus 10 according to the present invention as described above can shorten the molding time compared to the conventional transfer molding method using a plunger as the lens is manufactured by the injection molding method.

In this case, the present invention is a structure in which the insert mold part 200 provided with a plurality of cassette assemblies is mounted on the main mold part 100, and this can be injection molded at a time. It has the effect that it can be increased.

That is, even in the case of a conventional injection molding machine, multiple cavities can be formed in one core, but it is appropriate considering the moving distance of the resin injected through the runner, the size or shape of the product, and the size of the core itself. Since the number of cavities is designed by the number, the injection mold apparatus according to the present invention can have a plurality of such cores by mounting a plurality of insert mold parts 200, so as to have more than twice the number of cores installed. do.

In addition, the injection mold apparatus according to the present invention is made of a structure that can be easily detached from the insert mold part 200 as a fastening member to the main mold part 100, so it is easy to replace, so the shape or dimension of the molded product is changed. There is an effect that it is very easy to replace the core according to the like.

Moreover, since the injection mold apparatus according to the present invention can use the existing mold machine as it is, it has the advantage that it can significantly reduce the cost required for the production of a separate mold.

In particular, by installing a cold runner instead of a hot runner to mold a molded product made of silicone material, the silicone resin can be injected into the cavity while maintaining a low temperature to prevent solidification of the resin, and the cold of one block body Since the runner part 300 is provided with a structure capable of connecting a runner to a plurality of insert mold parts 200, it has an advantage that resin injection into each cavity is possible at the same time.

In addition to this, the injection mold apparatus according to the present invention, by mounting a second insert mold portion having a cavity of a different shape in order to produce a heterogeneous product or more products, that is, a plurality of molded products in one injection molding , It has the effect that it is possible to produce multiple varieties with one mold device. In other words, it is possible to form multiple products or to injection mold multiple (multiple) products at once, thereby increasing productivity.

On the other hand, since each insert mold part 200 is provided with an auxiliary heating means 450 designed to have a cavity, that is, an appropriate spacing and temperature corresponding to the shape or thickness of the product to be molded, the entire mold is replaced according to the core replacement. Not only does it not have to redesign the heating unit or reset the temperature of the heating unit, and it does not require temperature management for each core, so it has an effect of easy production management.

That is, when injection molding is performed by mounting additional insert mold portions having different cavities, it is difficult to manage heat for each core due to different shapes or sizes. In the injection mold apparatus according to the present invention, the main mold portion 100 Separately from the installed heating part 400, as the auxiliary heating means 450 is provided for each insert mold part 200, it has the advantage of easy individual management.

In other words, in the case of manufacturing a lens made of silicon with an existing injection molding mold, it was difficult to manage heat / temperature, such as heat shrinkage, depending on the thickness or shape of the lens, whereas the injection mold apparatus according to the present invention was used for each cavity. According to the shape of the auxiliary heating means 450 is provided, it has the advantage of easy heat / temperature management.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are for description, not for limiting the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments.

Therefore, the protection scope of the present invention should be interpreted by the following claims rather than limited by the above-described embodiments, and all technical spirits within the equivalent ranges should be interpreted as being included in the scope of the present invention.

10: injection mold device C: cavity
100: main mold 101: upper mold
102: lower mold 120: upper mold
130: upper frame 140: lower frame
150: lower plate
200: insert mold portion 220: insert upper core
230: insert lower core 300: cold runner part
400: heating unit 450: auxiliary heating means

Claims (5)

In the insert mold portion is installed inside the main mold portion of the cassette type mold apparatus for opening and closing operation,
The upper and lower mold plates, which are installed to open and close between the upper and lower fixing plates, and the upper frame, which is installed on the lower side of the upper mold plate to form the upper receiving groove on the mold surface, and the upper mold plate, are installed on the upper side of the lower mold plate. A main mold part including a lower frame in which a lower receiving groove is formed;
An insert mold part which is detachably installed in the receiving groove of the main mold part, and includes an insert upper core and an insert lower core which divide and form a cavity of a molded product on a molded surface;
A cold runner part installed in the main mold part to be connected to the insert mold part to inject silicone liquid resin into the cavity; And
A cassette-type injection mold for manufacturing a silicone molded product including a heating part having a first heating pipe and a second heating pipe to harden the silicone liquid resin by generating heat by being inserted through the upper mold plate and the lower mold plate of the main mold part, respectively. Device. The method according to claim 1,
A plurality of insert mold parts are provided, and each insert mold part is formed with a cavity having at least one shape as a cassette assembly,
Cassette type injection mold device for manufacturing a silicone molded product, characterized in that the auxiliary mold is installed in the insert mold portion. The method according to claim 2,
The auxiliary heating means includes a first auxiliary heating line positioned on the upper surface of the insert upper core and a second auxiliary heating line positioned on the lower surface of the insert lower core,
The heating lines are formed in a curved path in a curved shape along a horizontal plane, and a cassette-type injection mold apparatus for manufacturing a silicone molded product characterized in that it is formed in a different shape according to the shape of the product. The method according to claim 2 or claim 3,
The insert mold portion includes an insert upper fixing plate for fixing the insert upper core to the upper mold plate, and an insert fixing plate for fixing the insert lower core to the lower mold plate,
Cassette-type injection mold device for manufacturing a silicone molded product, characterized in that the insert mold is further provided with an insert take-out means that is installed on the lower side of the fixed plate to operate for taking out the molded product. The method according to claim 2 or claim 3,
Cassette-type injection mold device for manufacturing a silicone molded product, characterized in that each of the insert mold portion is provided with an insert take-out means for taking out the product individually.

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